生物合成硒蛋白机制的研究进展

作为第 2 1种氨基酸 ,硒代半胱氨酸在翻译阶段由核糖体介导 ,在mRNA编码区的UGA密码子处参入多肽链。研究表明硒代半胱氨酸的参入需要一个顺式作用元件SECIS和 4个基因产物 :SelA、SelB、SelC、SelD。原核生物和真核生物的SECIS在mRNA中的位置和结构特征差异显著。在利用Escherichiacoli硒代半胱氨酸的参入机制合成硒蛋白方面 ,研究人员进行了有益的探索。     

硒蛋白的生物合成与调控

硒蛋白是硒以硒半胱氨酸(Sec)形式参入形成的蛋白质。Sec作为参入蛋白质的第21种氨基酸,由硒蛋白mRNA上的UGA编码。在原核生物中,Sec参入硒蛋白的相关因子及其参入机制已基本阐明,Sec在SELA、SELB、SELC、SELD及Sec插入序列(SECIS)等的共同作用下参入到蛋白质中。在真核生物中,Sec参入硒蛋白的可能途径是：Ser-tRNA‘^[Ser]Sec。通过磷酸丝氨酰-tRNA^[Ser]Sec。最终转变为Sec-tRNA^[Ser]Sec,并在延伸因子及相关蛋白质因子的作用下参入到硒蛋白中。硒蛋白的合成在翻译前水平、mRNA水平、供硒水平等都受到相应的调控。     

硒蛋白的分子生物学研究进展

已有35种硒蛋白被分离和表征,但许多硒蛋白及其功能仍未完全阐明.硒半胱氨酸(Sec)作为参入蛋白质的第21种氨基酸,由硒蛋白mRNA上的UGA编码.在原核生物,Sec参入硒蛋白的复杂机制已经较为明确,需要四种基因产物（SELA、SELB、SELC和SELD）和一个存在于硒蛋白mRNA上的被称为Sec插入序列(SECIS)的茎环(stem loop)样二级结构.在真核生物,硒蛋白生物合成途径可能在SECIS的结构和位置、特异的延伸因子及其他RNA-RNA或RNA-蛋白质因子之间的相互作用等方面与原核生物不同.另外,哺乳动物硒蛋白mRNA上的UGA翻译为Sec的过程低效,特定位点的UGA密码子不同功能(终止密码和Sec密码)的调控可能是硒蛋白表达低效的关键.     

硒蛋白P的研究进展

微量元素硒 (Ｓｅ)作为许多具有重要生物功能的硒酶的活性中心 ,不但与机体的免疫应答及抗氧化作用等生理功能密切相关 ,而且能够降低癌症的发生率[1,2 ] 。在流行病学和临床研究中 ,常用血浆或全血中Ｓｅ浓度作为衡量Ｓｅ状态的指标 ,而且血浆浓度能比全血浓度更迅速地反映Ｓｅ状态的变化。在哺乳动物血浆中 ,Ｓｅ主要结合在 3种蛋白质中 :硒蛋白Ｐ、胞外谷胱甘肽过氧化物酶和清蛋白。其中硒蛋白Ｐ所含Ｓｅ大约占血浆中全部Ｓｅ浓度的 5 0 %。硒蛋白Ｐ不同于目前所鉴定的所有其他硒蛋白 ,因为它含有 10～ 12个硒代半胱氨酸 (ＳｅＣｙｓ)残…     

疟蚊基因组中新硒蛋白的计算机识别

硒蛋白的生物合成取决于硒代半胱氨酸插入蛋白质的过程. TGA码既是终止码、又可翻译成硒代半胱氨酸, 这使普通基因注释软件无法正确预测硒蛋白, 导致现有数据库中许多物种的硒蛋白被错误注释或丢失. 本研究基于已公布的疟蚊基因组预测信息、采用PERL语言编程, 对疟蚊基因组中的硒蛋白进行了计算机检索与分析. 结果表明: 以TGA码终止的基因有11365条, 其中具有SECIS结构的基因有918条, 同时具有半胱氨酸同源类似物的基因58条. 再经Sec侧翼序列比对, 最终检索到具有硒蛋白全部特点的基因7条. 从硒蛋白的基本生物功能推测, 冈比亚疟蚊基因组中存在的新硒蛋白可能与疟蚊的氧化耐受特性及其相关蛋白的调控相关联. 因此, 研究疟蚊硒蛋白将为干涉疟蚊带菌能力、从蚊媒传播途径防止疟疾提供理论基础.     

硒蛋白P的研究进展

硒蛋白P（SeP)是从大鼠和人血浆中分离,纯化得到的一种糖蛋白,每个硒蛋白P多肽含有10个硒代半胱氨酸,硒蛋白P中的硒含量占大鼠和人血浆中硒含量的50%以上,在其mRNA开放阅读框架中克隆的cDNA的序列含有10个UGA密码子。硒代半胱氨酸在一个UGA密码子处嵌入蛋白的一级结构,尽管对硒蛋白P功能还没有彻底了解,它的一种非常可能的作用是作为一种胞外抗氧化剂,大鼠血浆中的硒蛋白P在体内实验中对Diquat诱导的脂质过氧化和肝损坏具有保护作用,人血浆中的硒蛋白P在体外实验中显示减少内作为一存活促进因子。     

硒蛋白P的研究进展

硒蛋白P(SeP)是从大鼠和人血浆中分离、纯化得到的一种糖蛋白 ,每个硒蛋白P多肽含有10个硒代半胱氨酸。硒蛋白P中的硒含量占大鼠和人血浆中硒含量的 5 0 %以上。在其mRNA开放阅读框架中克隆的cDNA的序列含有 10个UGA密码子。硒代半胱氨酸在一个UGA密码子处嵌入蛋白的一级结构 ,尽管对硒蛋白P功能还没有彻底了解 ,它的一种非常可能的作用是作为一种胞外抗氧化剂。大鼠血浆中的硒蛋白P在体内实验中对Diquat诱导的脂质过氧化和肝损坏具有保护作用 ,人血浆中的硒蛋白P在体外实验中显示减少内毒素过氧化硝酸盐和磷脂氢过氧化物的活性。牛血浆中的硒蛋白P在神经细胞的培养中作为一存活促进因子。     

限制性内切酶Mlu I蛋白及其硒代衍生物的制备

【背景】限制性内切酶Mlu I是一种常用的工具酶,在分子生物学领域发挥着重要的作用,其三维结构尚未被解析。【目的】在大肠杆菌中克隆表达、纯化重组Mlu I蛋白及其硒代蛋白,并进行结晶条件的研究。【方法】构建重组表达载体pET28b-Mlu I,在大肠杆菌BL21(DE3)pLysS中诱导表达,利用亲和层析和凝胶过滤层析纯化重组Mlu I蛋白和硒代Mlu I蛋白。对蛋白进行质谱检测、圆二色谱检测以及酶活检测,利用坐滴法进行结晶条件的筛选。【结果】构建了重组表达载体pET28b-Mlu I并纯化获得达到结晶纯度的蛋白,通过质谱检测确定硒代Mlu I蛋白中的8个甲硫氨酸全部被取代,结合酶活测试及圆二色谱检测确定了硒代对Mlu I蛋白的活性、结构无明显影响。采用坐滴法进行初步的晶体生长研究,重组蛋白目前已在1种条件下获得针状晶体并进行初步衍射,获得分辨率在0.32 nm左右的衍射数据。【结论】Mlu I蛋白及硒代Mlu I蛋白纯化体系的构建和结晶条件的研究,可为下一步解析Mlu I三维结构、作用机制的探讨及定向改造奠定基础。     

硒蛋白合成的特殊机制

硒蛋白含有一种特殊氨基酸－硒代半胱氨酸。在翻译阶段,该氨基酸从硒蛋白ｍＲＮＡ编码区的ＵＧＡ密码子处掺入多肽链。已证明它由丝氨酸和活性硒供体分子合成。一种独特的ｔＲＮＡ,某些特殊蛋白质因子以及硒蛋白ｍＲＮＡ的特殊二级结构是ＵＧＡ解读为硒代半胱氨酸所必需的。     

与内含子相邻的核苷酸是tRNA内切酶的识别特征

含有内含子的tRNA前体必须经过剪接反应加工成熟.顺序比较指出与内含子顺序相邻的核苷酸有一定的特异性.用寡核苷酸定点突变技术改变这2个位点的核苷酸,确定这些tRNA前体的剪接效率.结果如下:当37位和38位都是嘌呤核苷酸时,tRNA内切酶能够有效地酶切酵母 tRNA~(phe)前体;如果其中的 1个位点变成嘧啶核苷酸,但另1个位点的核苷酸是野生型的嘌呤核苷酸,tRNA前体的酶切效率将降低.如果2个位点的核苷酸都发生变异,其中1个是嘧啶核苷酸,另1个是变异的嘌呤核苷酸,tRNA前体的酶切效率就会进一步降低.如果2个位点都是嘧啶核苷酸,tRNA前体就难以为tRNA内切酶酶切了.由此提出,与内含子相邻的核苷酸也是tRNA由切酶识别的结构特征.tRNA前体的37位和38位核苷酸的改变可能影响剪接位点之间的距离或它们的精细结构,从而影响tRNA内切酶酶切的效率.     

The Specific Elongation Factor to Selenocysteine Incorporation in Escherichia coli: Unique tRNASec Recognition and its Interactions

Several molecular mechanisms are involved in the genetic code interpretation during translation, as codon degeneration for the incorporation of rare amino acids. One mechanism that stands out is selenocysteine (Sec), which requires a specific biosynthesis and incorporation pathway. In Bacteria, the Sec biosynthesis pathway has unique features compared with the eukaryote pathway as Ser to Sec conversion mechanism is accomplished by a homodecameric enzyme (selenocysteine synthase, SelA) followed by the action of an elongation factor (SelB) responsible for delivering the mature Sec-tRNA^Sec into the ribosome by the interaction with the Selenocysteine Insertion Sequence (SECIS). Besides this mechanism being already described, the sequential events for Sec-tRNA^Sec and SECIS specific recognition remain unclear. In this study, we determined the order of events of the interactions between the proteins and RNAs involved in Sec incorporation. Dissociation constants between SelB and the native as well as unacylated-tRNA^Sec variants demonstrated that the acceptor stem and variable arm are essential for SelB recognition. Moreover, our data support the sequence of molecular events where GTP-activated SelB strongly interacts with SelA.tRNA^Sec. Subsequently, SelB.GTP.tRNA^Sec recognizes the mRNA SECIS to deliver the tRNA^Sec to the ribosome. SelB in complex with its specific RNAs were examined using Hydrogen/Deuterium exchange mapping that allowed the determination of the molecular envelopes and its secondary structural variations during the complex assembly. Our results demonstrate the ordering of events in Sec incorporation and contribute to the full comprehension of the tRNA^Sec role in the Sec amino acid biosynthesis, as well as extending the knowledge of synthetic biology and the expansion of the genetic code.     

Evolution of selenium utilization traits

Background  

The essential trace element selenium is used in a wide variety of biological processes. Selenocysteine (Sec), the 21st amino acid, is co-translationally incorporated into a restricted set of proteins. It is encoded by an UGA codon with the help of tRNA^Sec (SelC), Sec-specific elongation factor (SelB) and a cis-acting mRNA structure (SECIS element). In addition, Sec synthase (SelA) and selenophosphate synthetase (SelD) are involved in the biosynthesis of Sec on the tRNA^Sec. Selenium is also found in the form of 2-selenouridine, a modified base present in the wobble position of certain tRNAs, whose synthesis is catalyzed by YbbB using selenophosphate as a precursor.     

New Developments in Selenium Biochemistry: Selenocysteine Biosynthesis in Eukaryotes and Archaea

We used comparative genomics and experimental analyses to show that (1) eukaryotes and archaea, which possess the selenocysteine (Sec) protein insertion machinery contain an enzyme, O-phosphoseryl-transfer RNA (tRNA)^[Ser]Sec kinase (designated PSTK), which phosphorylates seryl-tRNA^[Ser]Sec to form O-phosphoseryl-tRNA^[Ser]Sec and (2) the Sec synthase (SecS) in mammals is a pyridoxal phosphate-containing protein previously described as the soluble liver antigen (SLA). SecS uses the product of PSTK, O-phosphoseryl-tRNA^[Ser]Sec, and selenophosphate as substrates to generate selenocysteyl-tRNA^[Ser]Sec. Sec could be synthesized on tRNA^[Ser]Sec from selenide, adenosine triphosphate (ATP), and serine using tRNA^[Ser]Sec, seryl-tRNA synthetase, PSTK, selenophosphate synthetase, and SecS. The enzyme that synthesizes monoselenophosphate is a previously identified selenoprotein, selenophosphate synthetase 2 (SPS2), whereas the previously identified mammalian selenophosphate synthetase 1 did not serve this function. Monoselenophosphate also served directly in the reaction replacing ATP, selenide, and SPS2, demonstrating that this compound was the active selenium donor. Conservation of the overall pathway of Sec biosynthesis suggests that this pathway is also active in other eukaryotes and archaea that contain selenoproteins. X.-M. Xu and B. A. Carlson contributed equally to the studies described herein.     

Dimer–Dimer Interaction of the Bacterial Selenocysteine Synthase SelA Promotes Functional Active-Site Formation and Catalytic Specificity

The 21st amino acid, selenocysteine (Sec), is incorporated translationally into proteins and is synthesized on its specific tRNA (tRNA^Sec). In Bacteria, the selenocysteine synthase SelA converts Ser-tRNA^Sec, formed by seryl-tRNA synthetase, to Sec-tRNA^Sec. SelA, a member of the fold-type-I pyridoxal 5′-phosphate-dependent enzyme superfamily, has an exceptional homodecameric quaternary structure with a molecular mass of about 500 kDa. Our previously determined crystal structures of Aquifex aeolicus SelA complexed with tRNA^Sec revealed that the ring-shaped decamer is composed of pentamerized SelA dimers, with two SelA dimers arranged to collaboratively interact with one Ser-tRNA^Sec. The SelA catalytic site is close to the dimer–dimer interface, but the significance of the dimer pentamerization in the catalytic site formation remained elusive. In the present study, we examined the quaternary interactions and demonstrated their importance for SelA activity by systematic mutagenesis. Furthermore, we determined the crystal structures of “depentamerized” SelA variants with mutations at the dimer–dimer interface that prevent pentamerization. These dimeric SelA variants formed a distorted and inactivated catalytic site and confirmed that the pentamer interactions are essential for productive catalytic site formation. Intriguingly, the conformation of the non-functional active site of dimeric SelA shares structural features with other fold-type-I pyridoxal 5′-phosphate-dependent enzymes with native dimer or tetramer (dimer-of-dimers) quaternary structures.     

Crystal structure of the full-length bacterial selenocysteine-specific elongation factor SelB

Selenocysteine (Sec), the 21^st amino acid in translation, uses its specific tRNA (tRNA^Sec) to recognize the UGA codon. The Sec-specific elongation factor SelB brings the selenocysteinyl-tRNA^Sec (Sec-tRNA^Sec) to the ribosome, dependent on both an in-frame UGA and a Sec-insertion sequence (SECIS) in the mRNA. The bacterial SelB binds mRNA through its C-terminal region, for which crystal structures have been reported. In this study, we determined the crystal structure of the full-length SelB from the bacterium Aquifex aeolicus, in complex with a GTP analog, at 3.2-Å resolution. SelB consists of three EF-Tu-like domains (D1–3), followed by four winged-helix domains (WHD1–4). The spacer region, connecting the N- and C-terminal halves, fixes the position of WHD1 relative to D3. The binding site for the Sec moiety of Sec-tRNA^Sec is located on the interface between D1 and D2, where a cysteine molecule from the crystallization solution is coordinated by Arg residues, which may mimic Sec binding. The Sec-binding site is smaller and more exposed than the corresponding site of EF-Tu. Complex models of Sec-tRNA^Sec, SECIS RNA, and the 70S ribosome suggest that the unique secondary structure of tRNA^Sec allows SelB to specifically recognize tRNA^Sec and characteristically place it at the ribosomal A-site.     

Loss of housekeeping selenoprotein expression in mouse liver modulates lipoprotein metabolism

Selenium is incorporated into proteins as selenocysteine (Sec), which is dependent on its specific tRNA, designated tRNA^[Ser]Sec. Targeted removal of the tRNA^[Ser]Sec gene (Trsp) in mouse hepatocytes previously demonstrated the importance of selenoproteins in liver function. Herein, analysis of plasma proteins in this Trsp knockout mouse revealed increases in apolipoprotein E (ApoE) that was accompanied by elevated plasma cholesterol levels. The expression of genes involved in cholesterol biosynthesis, metabolism and transport were also altered in knockout mice. Additionally, in two transgenic Trsp mutant mouse lines (wherein only housekeeping selenoprotein synthesis was restored), the expression of ApoE, as well as genes involved in cholesterol biosynthesis, metabolism and transport were similar to those observed in wild type mice. These data correlate with reports that selenium deficiency results in increased levels of ApoE, indicating for the first time that housekeeping selenoproteins have a role in regulating lipoprotein biosynthesis and metabolism.     

Structural Asymmetry of the Terminal Catalytic Complex in Selenocysteine Synthesis

Selenocysteine (Sec), the 21^st amino acid, is synthesized from a serine precursor in a series of reactions that require selenocysteine tRNA (tRNA^Sec). In archaea and eukaryotes, O-phosphoseryl-tRNA^Sec:selenocysteinyl-tRNA^Sec synthase (SepSecS) catalyzes the terminal synthetic reaction during which the phosphoseryl intermediate is converted into the selenocysteinyl moiety while being attached to tRNA^Sec. We have previously shown that only the SepSecS tetramer is capable of binding to and recognizing the distinct fold of tRNA^Sec. Because only two of the four tRNA-binding sites were occupied in the crystal form, a question was raised regarding whether the observed arrangement and architecture faithfully recapitulated the physiologically relevant ribonucleoprotein complex important for selenoprotein formation. Herein, we determined the stoichiometry of the human terminal synthetic complex of selenocysteine by using small angle x-ray scattering, multi-angle light scattering, and analytical ultracentrifugation. In addition, we provided the first estimate of the ratio between SepSecS and tRNA^Sec in vivo. We show that SepSecS preferentially binds one or two tRNA^Sec molecules at a time and that the enzyme is present in large molar excess over the substrate tRNA in vivo. Moreover, we show that in a complex between SepSecS and two tRNAs, one enzyme homodimer plays a role of the noncatalytic unit that positions CCA ends of two tRNA^Sec molecules into the active site grooves of the other, catalytic, homodimer. Finally, our results demonstrate that the previously determined crystal structure represents the physiologically and catalytically relevant complex and suggest that allosteric regulation of SepSecS might play an important role in regulation of selenocysteine and selenoprotein synthesis.     

Thermodynamic and Kinetic Framework of Selenocysteyl-tRNASec Recognition by Elongation Factor SelB

SelB is a specialized translation elongation factor that delivers selenocysteyl-tRNA^Sec (Sec-tRNA^Sec) to the ribosome. Here we show that Sec-tRNA^Sec binds to SelB·GTP with an extraordinary high affinity (K_d = 0.2 pm). The tight binding is driven enthalpically and involves the net formation of four ion pairs, three of which may involve the Sec residue. The dissociation of tRNA from the ternary complex SelB·GTP·Sec-tRNA^Sec is very slow (0.3 h⁻¹), and GTP hydrolysis accelerates the release of Sec-tRNA^Sec by more than a million-fold (to 240 s⁻¹). The affinities of Sec-tRNA^Sec to SelB in the GDP or apoforms, or Ser-tRNA^Sec and tRNA^Sec to SelB in any form, are similar (K_d = 0.5 μm). Thermodynamic coupling in binding of Sec-tRNA^Sec and GTP to SelB ensures at the same time the specificity of Sec- versus Ser-tRNA^Sec selection and rapid release of Sec-tRNA^Sec from SelB after GTP cleavage on the ribosome. SelB provides an example for the evolution of a highly specialized protein-RNA complex toward recognition of unique set of identity elements. The mode of tRNA recognition by SelB is reminiscent of another specialized factor, eIF2, rather than of EF-Tu, the common delivery factor for all other aminoacyl-tRNAs, in line with a common evolutionary ancestry of SelB and eIF2.     

Inhibition of Cellular Methyltransferases Promotes Endothelial Cell Activation by Suppressing Glutathione Peroxidase 1 Protein Expression

S-Adenosylhomocysteine (SAH) is a negative regulator of most methyltransferases and the precursor for the cardiovascular risk factor homocysteine. We have previously identified a link between the homocysteine-induced suppression of the selenoprotein glutathione peroxidase 1 (GPx-1) and endothelial dysfunction. Here we demonstrate a specific mechanism by which hypomethylation, promoted by the accumulation of the homocysteine precursor SAH, suppresses GPx-1 expression and leads to inflammatory activation of endothelial cells. The expression of GPx-1 and a subset of other selenoproteins is dependent on the methylation of the tRNA^Sec to the Um34 form. The formation of methylated tRNA^Sec facilitates translational incorporation of selenocysteine at a UGA codon. Our findings demonstrate that SAH accumulation in endothelial cells suppresses the expression of GPx-1 to promote oxidative stress. Hypomethylation stress, caused by SAH accumulation, inhibits the formation of the methylated isoform of the tRNA^Sec and reduces GPx-1 expression. In contrast, under these conditions, the expression and activity of thioredoxin reductase 1, another selenoprotein, is increased. Furthermore, SAH-induced oxidative stress creates a proinflammatory activation of endothelial cells characterized by up-regulation of adhesion molecules and an augmented capacity to bind leukocytes. Taken together, these data suggest that SAH accumulation in endothelial cells can induce tRNA^Sec hypomethylation, which alters the expression of selenoproteins such as GPx-1 to contribute to a proatherogenic endothelial phenotype.